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. 2012 Dec 1;21(23):5222-8.
doi: 10.1093/hmg/dds361. Epub 2012 Aug 30.

Genome-wide association study identifies a new locus JMJD1C at 10q21 that may influence serum androgen levels in men

Guangfu Jin  1 Jielin SunSeong-Tae KimJunjie FengZhong WangSha TaoZhuo ChenLina PurcellShelly SmithWilliam B IsaacsRoger S RittmasterS Lilly ZhengLynn D CondreayJianfeng Xu
Affiliations

Genome-wide association study identifies a new locus JMJD1C at 10q21 that may influence serum androgen levels in men

Guangfu Jin et al. Hum Mol Genet. .

Abstract

Circulating androgen levels are often used as indicators of physiological or pathological conditions. More than half of the variance for circulating androgen levels is thought to be genetically influenced. A genome-wide association study (GWAS) has identified two loci, SHBG at 17p13 and FAM9B at Xp22, for serum testosterone (T) levels; however, these explain only a small fraction of inter-individual variability. To identify additional genetic determinants of androgen levels, a GWAS of baseline serum T and dihydrotestosterone (DHT) levels was conducted in 3225 men of European ancestry from the REduction by DUtasteride of Prostate Cancer Events (REDUCE) study. Cross-validation was used to confirm the observed associations between the drug (n = 1581) and placebo (n = 1644) groups of REDUCE. In addition to confirming the associations of two known loci with serum T levels (rs727428 in SHBG: P = 1.26 × 10(-12); rs5934505 in FAM9B: P = 1.61 × 10(-8)), we identified a new locus, JMJD1C at 10q21 that was associated with serum T levels at a genome-wide significance level (rs10822184: P = 1.12 × 10(-8)). We also observed that the SHBG locus was associated with serum DHT levels (rs727428: P = 1.47 × 10(-11)). Moreover, two additional variants in SHBG [rs72829446, in strong linkage equilibrium with the missense variant D356N (rs6259), and rs1799941] were also independently associated with circulating androgen levels in a statistical scale. These three loci (JMJD1C, SHBG and FAM9B) were estimated to account for ~5.3 and 4.1% of the variance of serum T and DHT levels. Our findings may provide new insights into the regulation of circulating androgens and potential targets for androgen-based therapy.

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Figures

Figure 1.
Figure 1.
Manhattan plots of the strength of associations (–log10 P values; Y-axis) between SNPs (X-axis by chromosome and chromosomal position) and serum levels of testosterone (A) and DHT (B).
Figure 2.
Figure 2.
Regional plot of the associations between SNPs at 10q21 and serum testosterone levels. Association of individual SNP is plotted as −log10 P against the chromosomal position. Results of both genotyped and imputed SNPs are shown. Colors indicate the LD strength between the most significant SNP rs10822184 and the other SNPs assessed. The right Y-axis shows the recombination rate estimated from the 1000 Genomes CEU population.
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